%% This BibTeX bibliography file was created using BibDesk.
%% https://bibdesk.sourceforge.io/

%% Created for circle at 2023-03-27 8:37:20 PM +0800 


%% Saved with string encoding Unicode (UTF-8) 

@article{emran_shishkina_2020,
  title     = {Natural convection in cylindrical containers with isothermal ring-shaped obstacles},
  volume    = {882},
  doi       = {10.1017/jfm.2019.797},
  journal   = {Journal of Fluid Mechanics},
  publisher = {Cambridge University Press},
  author    = {Emran, Mohammad S. and Shishkina, Olga},
  year      = {2020},
  pages     = {A3}
}

@article{zhuRoughnessFacilitatedLocalScaling2017,
  author        = {Zhu, Xiaojue and Stevens, Richard J. A. M. and Verzicco, Roberto and Lohse, Detlef},
  date          = {2017-10-11},
  date-added    = {2023-03-27 8:12:44 PM +0800},
  date-modified = {2023-03-27 8:37:18 PM +0800},
  doi           = {10.1103/PhysRevLett.119.154501},
  issn          = {0031-9007, 1079-7114},
  journaltitle  = {Physical Review Letters},
  langid        = {english},
  number        = {15},
  pages         = {154501},
  shortjournal  = {Phys. Rev. Lett.},
  title         = {Roughness-{{Facilitated Local}} 1 / 2 {{Scaling Does Not Imply}} the {{Onset}} of the {{Ultimate Regime}} of {{Thermal Convection}}},
  url           = {https://link.aps.org/doi/10.1103/PhysRevLett.119.154501},
  urldate       = {2023-02-15},
  volume        = {119},
  year          = {2017},
  bdsk-url-1    = {https://link.aps.org/doi/10.1103/PhysRevLett.119.154501},
  bdsk-url-2    = {https://doi.org/10.1103/PhysRevLett.119.154501}
}

@article{xieTurbulentThermalConvection2017,
  author        = {Xie, Yi-Chao and Xia, Ke-Qing},
  date-added    = {2023-03-27 8:07:07 PM +0800},
  date-modified = {2023-03-27 8:10:29 PM +0800},
  doi           = {10.1017/jfm.2017.397},
  issn          = {0022-1120, 1469-7645},
  journal       = {Journal of Fluid Mechanics},
  langid        = {english},
  month         = aug,
  pages         = {573--599},
  title         = {Turbulent Thermal Convection over Rough Plates with Varying Roughness Geometries},
  urldate       = {2023-02-15},
  volume        = {825},
  year          = {2017},
  bdsk-url-1    = {https://doi.org/10.1017/jfm.2017.397}
}

@article{yang2020periodically-mo,
  author        = {Yang, Rui and Chong, Kai Leong and Wang, Qi and Verzicco, Roberto and Shishkina, Olga and Lohse, Detlef},
  date-added    = {2022-10-25 10:18:49 AM +0800},
  date-modified = {2022-10-25 10:18:49 AM +0800},
  doi           = {10.1103/PhysRevLett.125.154502},
  issue         = {15},
  journal       = {Phys. Rev. Lett.},
  month         = {Oct},
  numpages      = {6},
  pages         = {154502},
  publisher     = {American Physical Society},
  title         = {Periodically Modulated Thermal Convection},
  url           = {https://link.aps.org/doi/10.1103/PhysRevLett.125.154502},
  volume        = {125},
  year          = {2020},
  bdsk-file-1   = {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},
  bdsk-url-1    = {https://link.aps.org/doi/10.1103/PhysRevLett.125.154502},
  bdsk-url-2    = {https://doi.org/10.1103/PhysRevLett.125.154502}
}

@article{wang2020vibration-induc,
  abstract      = {We conceptualize an elegant mechanism of thermal vibrational turbulence that achieves massive heat-transport enhancement. Thermal turbulence is well known as a potent means to convey heat across space by a moving fluid. The existence of the boundary layers near the plates, however, bottlenecks its heat-exchange capability. Here, we conceptualize a mechanism of thermal vibrational turbulence that breaks through the boundary-layer limitation and achieves massive heat-transport enhancement. When horizontal vibration is applied to the convection cell, a strong shear is induced to the body of fluid near the conducting plates, which destabilizes thermal boundary layers, vigorously triggers the eruptions of thermal plumes, and leads to a heat-transport enhancement by up to 600\%. We further reveal that such a vibration-induced shear can very efficiently disrupt the boundary layers. The present findings open a new avenue for research into heat transport and will also bring profound changes in many industrial applications where thermal flux through a fluid is involved and the mechanical vibration is usually inevitable.},
  author        = {Bo-Fu Wang and Quan Zhou and Chao Sun},
  date-added    = {2022-10-22 4:04:26 PM +0800},
  date-modified = {2022-10-22 4:04:26 PM +0800},
  doi           = {10.1126/sciadv.aaz8239},
  eprint        = {https://www.science.org/doi/pdf/10.1126/sciadv.aaz8239},
  journal       = {Science Advances},
  number        = {21},
  pages         = {eaaz8239},
  title         = {Vibration-induced boundary-layer destabilization achieves massive heat-transport enhancement},
  url           = {https://www.science.org/doi/abs/10.1126/sciadv.aaz8239},
  volume        = {6},
  year          = {2020},
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  bdsk-url-1    = {https://www.science.org/doi/abs/10.1126/sciadv.aaz8239},
  bdsk-url-2    = {https://doi.org/10.1126/sciadv.aaz8239}
}

@article{xia2013current-trends-,
  abstract      = {The system of turbulent thermal convection is introduced. Progresses in recent decades in the four major areas of research in turbulent convection are briefly reviewed. Some of the recent trends of the field are then discussed, which also serve to point out that the future directions in this important field of fluid mechanics lie in the extension to the non-standard or non-classical Rayleigh---B{\'e}nard configuration.},
  author        = {Ke-Qing Xia},
  date-added    = {2022-10-22 12:48:55 PM +0800},
  date-modified = {2022-10-22 12:48:55 PM +0800},
  doi           = {https://doi.org/10.1063/2.1305201},
  issn          = {2095-0349},
  journal       = {Theoretical and Applied Mechanics Letters},
  keywords      = {turbulence, thermal convection, turbulent heat transport, thermal plumes, large-scale flow, small-scale turbulence},
  number        = {5},
  pages         = {052001},
  title         = {Current trends and future directions in turbulent thermal convection},
  url           = {https://www.sciencedirect.com/science/article/pii/S2095034915302531},
  volume        = {3},
  year          = {2013},
  bdsk-file-1   = {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},
  bdsk-url-1    = {https://www.sciencedirect.com/science/article/pii/S2095034915302531},
  bdsk-url-2    = {https://doi.org/10.1063/2.1305201}
}

@article{ahlers2009heat-transfer-a,
  author        = {Ahlers, Guenter and Grossmann, Siegfried and Lohse, Detlef},
  date-added    = {2022-10-15 4:21:58 PM +0800},
  date-modified = {2022-10-15 4:21:58 PM +0800},
  doi           = {10.1103/RevModPhys.81.503},
  issue         = {2},
  journal       = {Rev. Mod. Phys.},
  month         = {Apr},
  numpages      = {0},
  pages         = {503--537},
  publisher     = {American Physical Society},
  title         = {Heat transfer and large scale dynamics in turbulent Rayleigh-B\'enard convection},
  url           = {https://link.aps.org/doi/10.1103/RevModPhys.81.503},
  volume        = {81},
  year          = {2009},
  bdsk-file-1   = {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},
  bdsk-url-1    = {https://link.aps.org/doi/10.1103/RevModPhys.81.503},
  bdsk-url-2    = {https://doi.org/10.1103/RevModPhys.81.503}
}

@article{grossmann2001,
  author        = {Grossmann, S. and Lohse, D.},
  date-added    = {2022-10-12 10:20:41 AM +0800},
  date-modified = {2022-10-12 10:20:41 AM +0800},
  journal       = {Phys. Rev. Lett.},
  number        = {15},
  pages         = {3316--3319},
  publisher     = {APS},
  title         = {{Thermal convection for large Prandtl numbers}},
  volume        = {86},
  year          = {2001}
}

@article{grossmann2000,
  author        = {Grossmann, S. and Lohse, D.},
  date-added    = {2022-10-12 10:20:33 AM +0800},
  date-modified = {2022-10-12 10:20:33 AM +0800},
  journal       = {J.Fluid Mech.},
  pages         = {27--56},
  publisher     = {Cambridge University Press},
  title         = {Scaling in thermal convection: a unifying theory},
  volume        = {407},
  year          = {2000}
}

@article{kraichnan1962turbulent-therm,
  author        = {Kraichnan,Robert H.},
  date-added    = {2022-10-12 10:18:37 AM +0800},
  date-modified = {2022-10-12 10:18:37 AM +0800},
  doi           = {10.1063/1.1706533},
  eprint        = {https://aip.scitation.org/doi/pdf/10.1063/1.1706533},
  journal       = {The Physics of Fluids},
  number        = {11},
  pages         = {1374-1389},
  title         = {Turbulent Thermal Convection at Arbitrary Prandtl Number},
  url           = {https://aip.scitation.org/doi/abs/10.1063/1.1706533},
  volume        = {5},
  year          = {1962},
  bdsk-file-1   = {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},
  bdsk-url-1    = {https://aip.scitation.org/doi/abs/10.1063/1.1706533},
  bdsk-url-2    = {https://doi.org/10.1063/1.1706533}
}

@article{malkus1954the-heat-transp,
  abstract      = {In this paper a theoretical investigation is made of various properties of the steady-state inhomogeneous turbulent convection of heat in a fluid between horizontal conducting surfaces. An upper limit to the heat transport is found subject to the constraint that some minimum eddy size exists which is effective in this transport. The spectrum of convecting motions, the mean thermal gradients at each point and the eddy conductivity are then determined in terms of the minimum eddy size. The relation between the boundary conditions and eddy size is studied by an extension of the work of Pellew & Southwell using the mean thermal gradients deduced when n0 modes of motion are present to establish the Rayleigh number at which the (n0 + 1)th mode first becomes unstable. In a final section the spectra and mean-square values of the fluctuating velocity and temperature fields are estimated from the Boussinesq form of the hydrodynamic equations. The previously reported experimental heat transports are within 10% of those predicted. The discrete transitions are within the error limits of the observations. However, further data must be gathered to justify the use of minimum eddy size as a defining parameter in situations of geophysical scale.},
  author        = {W. V. R. Malkus},
  date-added    = {2022-10-12 10:06:21 AM +0800},
  date-modified = {2022-10-12 10:06:21 AM +0800},
  issn          = {00804630},
  journal       = {Proceedings of the Royal Society of London. Series A, Mathematical and Physical Sciences},
  number        = {1161},
  pages         = {196--212},
  publisher     = {The Royal Society},
  title         = {The Heat Transport and Spectrum of Thermal Turbulence},
  url           = {http://www.jstor.org/stable/99409},
  urldate       = {2022-10-09},
  volume        = {225},
  year          = {1954},
  bdsk-file-1   = {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},
  bdsk-url-1    = {http://www.jstor.org/stable/99409}
}

@article{fadlun2000combined-immers,
  abstract      = {A second-order accurate, highly efficient method is developed for simulating unsteady three-dimensional incompressible flows in complex geometries. This is achieved by using boundary body forces that allow the imposition of the boundary conditions on a given surface not coinciding with the computational grid. The governing equations, therefore, can be discretized and solved on a regular mesh thus retaining the advantages and the efficiency of the standard solution procedures. Two different forcings are tested showing that while the quality of the results is essentially the same in both cases, the efficiency of the calculation strongly depends on the particular expression. A major issue is the interpolation of the forcing over the grid that determines the accuracy of the scheme; this ranges from zeroth-order for the most commonly used interpolations up to second-order for an ad hoc velocity interpolation. The present scheme has been used to simulate several flows whose results have been validated by experiments and other results available in the literature. Finally in the last example we show the flow inside an IC piston/cylinder assembly at high Reynolds number; to our knowledge this is the first example in which the immersed boundary technique is applied to a full three-dimensional complex flow with moving boundaries and with a Reynolds number high enough to require a subgrid-scale turbulence model.},
  author        = {E.A. Fadlun and R. Verzicco and P. Orlandi and J. Mohd-Yusof},
  date-added    = {2022-10-11 2:38:18 PM +0800},
  date-modified = {2022-10-11 2:38:18 PM +0800},
  doi           = {https://doi.org/10.1006/jcph.2000.6484},
  issn          = {0021-9991},
  journal       = {Journal of Computational Physics},
  number        = {1},
  pages         = {35-60},
  title         = {Combined Immersed-Boundary Finite-Difference Methods for Three-Dimensional Complex Flow Simulations},
  url           = {https://www.sciencedirect.com/science/article/pii/S0021999100964842},
  volume        = {161},
  year          = {2000},
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  bdsk-url-1    = {https://www.sciencedirect.com/science/article/pii/S0021999100964842},
  bdsk-url-2    = {https://doi.org/10.1006/jcph.2000.6484}
}

@article{mittal2005immersed-bounda,
  author        = {Mittal, Rajat and Iaccarino, Gianluca},
  date-added    = {2022-10-11 2:38:02 PM +0800},
  date-modified = {2022-10-11 2:38:02 PM +0800},
  doi           = {10.1146/annurev.fluid.37.061903.175743},
  eprint        = {https://doi.org/10.1146/annurev.fluid.37.061903.175743},
  journal       = {Annual Review of Fluid Mechanics},
  number        = {1},
  pages         = {239-261},
  title         = {IMMERSED BOUNDARY METHODS},
  url           = {https://doi.org/10.1146/annurev.fluid.37.061903.175743},
  volume        = {37},
  year          = {2005},
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  bdsk-url-1    = {https://doi.org/10.1146/annurev.fluid.37.061903.175743}
}
